Carbon nanotubes carry plasmonic signals in the terahertz range of the electromagnetic spectrum, but only if they’re metallic by nature or doped. In new research, the Rice Univ. laboratory of physicist Junichiro Kono disproved previous theories that dominant terahertz response comes from narrow-gap semiconducting nanotubes.
The prospect of turning coal into fluorescent particles may sound too good to be true, but the...
When engineers design devices, they must often join together two materials that expand and...
Univ. of Illinois researchers have developed a way to heal gaps in wires too small for even the...
Massachusetts Institute of Technology chemical engineers have developed a novel way to generate nanoparticles that can recognize specific molecules, opening up a new approach to building durable sensors for many different compounds, among other applications. To create these “synthetic antibodies,” the researchers used carbon nanotubes.
It’s not x-ray vision, but you could call it infrared vision. A Univ. at Buffalo-led research team has developed a technique for “seeing through” a stack of graphene sheets to identify and describe the electronic properties of each individual sheet, even when the sheets are covering each other up.
Northwestern Univ. and Argonne National Laboratory scientists have recently overcome problems with growing graphene on chemically inert substrates, demonstrating the first growth of graphene on a single-crystal silver substrate. Their method could advance graphene-based optical devices and enable the interfacing of graphene with other two-dimensional materials.
One of the methods used for examining the molecules in a liquid consists in passing the fluid through a nano-sized hole so as to detect their passage. Researchers in Switzerland have found a way to improve this technique by using a material with unique properties: graphene.
A team of scientists have demonstrated new application of graphene using positive feedback. Using graphene’s electrical conduction, Columbia Univ. engineers have created a nano-mechanical system that can create FM signals. It is, in effect, the world's smallest FM radio transmitter.
Despite their almost incomprehensibly small size, single-walled carbon nanotubes come in a plethora of different “species,” each with its own structure and unique combination of electronic and optical properties. Characterizing the structure and properties of an individual carbon nanotube has involved a lot of guesswork, until now.
Commercially available as instrumentation designed for macro-size sampling, Raman spectroscopy drew interest for providing information similar but complementary to infrared (FTIR) spectroscopy for chemical identification. In addition to chemical fingerprinting, the technique could provide molecular backbone information, materials morphology, sensitivity to symmetric bonds and the ability to analyze inorganic samples and components.
Researchers from the NIST Center for Nanoscale Science and Technology (CNST) and the Republic of Korea's national metrology institute—the Korea Research Institute of Standards and Science (KRISS)—have recently developed a unique nanoscale measurement technique and used it to observe structural disorder in graphene that is fabricated on a silicon carbide substrate
Researchers from Lawrence Livermore National Laboratory (LLNL) and the Swiss Federal Institute of Technology (ETH) in Zurich have developed a new method of using nanotubes to detect molecules at extremely low concentrations enabling trace detection of biological threats, explosives and drugs.
A theoretical, three-dimensional (3D) form of carbon that is metallic under ambient temperature and pressure has been discovered by an international research team. The findings, which may significantly advance carbon science, are published online this week
The Toronto-based luxury bespoke tailoring house Garrison Bespoke launched the first fashion-forward bulletproof suit with a live ammo field-testing event at the Ajax Rod and Gun Club at in Ontario. The Garrison Bespoke bulletproof suit is made with carbon nanotubes created using nanotechnology and originally developed to protect U.S. forces in Iraq. The patented material is thinner, more flexible and 50% lighter than Kevlar.
Researchers at NJIT have developed a flexible battery made with carbon nanotubes that could potentially power electronic devices with flexible displays. According to its developers, this battery can be made as small as a pinhead or as large as a carpet in a living room.
Univ. of Delaware materials scientists have successfully developed a compact, stretchable wire-shaped supercapacitor based on continuous carbon nanotube fibers. When subjected to a tensile strain of 100% over 10,000 charge/discharge cycles, the CNT supercapacitor’s electrochemical performance improved to 108%.
Nitric oxide (NO) is one of the most important signaling molecules in living cells, carrying messages within the brain and coordinating immune system functions. In many cancerous cells, levels are perturbed, but very little is known about how NO behaves in both healthy and cancerous cells. Until now.
Researchers in Basque country in Spain have developed and patented a new source of light emitter based on boron nitride nanotubes. Suitable for developing high-efficiency optoelectronic devices, the structural defects in the nanotubes help make it extremely efficient in ultraviolet light emission.
The direct emission of terahertz radiation would be useful in science, but no laser has yet been developed which can provide it. A team headed of researchers have now demonstrated that graphene meets an important condition for use in novel lasers for terahertz pulses with long wavelengths: It permits population inversion, a key prerequisite for stimulated radiation emission.
A huge plastic balloon floated high in the skies over New Mexico on Sept. 29, 2013, carrying instruments to collect climate-related test data with the help of carbon nanotube chips made by NIST. The onboard instrument was an experimental spectrometer designed to collect and measure visible and infrared wavelengths of light ranging from 350 to 2,300 nm.
Researchers in electrical and computer engineering at the Univ. of California, Santa Barbara have introduced and modeled an integrated circuit design scheme in which transistors and interconnects are monolithically patterned seamlessly on a sheet of graphene. The demonstration offers possibilities for ultra-energy-efficient, flexible and transparent electronics.
A discovery at Rice Univ. aims to make vehicles that run on compressed natural gas more practical. It might also prolong the shelf life of bottled beer and soda. The Rice laboratory of chemist James Tour has enhanced a polymer material to make it far more impermeable to pressurized gas and far lighter than the metal in tanks now used to contain the gas.
Writing in Nature Communications, researchers at The Univ. of Manchester and the Karlsruhe Institute of Technology have demonstrated that membranes can be directly 'written' on to a graphene surface using a technique known as Lipid Dip-Pen Nanolithography (L-DPN).
Carbyne will be the strongest of a new class of microscopic materials if and when anyone can make it in bulk. If they do, they’ll find carbyne nanorods or nanoropes have a host of remarkable and useful properties, as described in a paper by Rice Univ. theoretical physicist Boris Yakobson and his group.
Researchers at the Helmholtz Zentrum Berlin Institute for Silicon Photovoltaics have shown that graphene retains its impressive set of properties when it is coated with a thin silicon film. These findings have paved the way for entirely new possibilities to use in thin-film photovoltaics. Graphene has extreme conductivity and is completely transparent while being inexpensive and nontoxic.
Atomically thin sheets of hexagonal boron nitride (h-BN) have the handy benefit of protecting what’s underneath from oxidizing even at very high temperatures, Rice Univ. researchers have discovered. One or several layers of the material sometimes called “white graphene” keep materials from oxidizing up to 1,100 C (2,012 F), and can be made large enough for industrial applications, they said.
A new study has found that “waviness” in forests of vertically-aligned carbon nanotubes dramatically reduces their stiffness, answering a long-standing question surrounding the tiny structures. Instead of being a detriment, the waviness may make the nanotube arrays more compliant and therefore useful as thermal interface material for conducting heat away from future high-powered integrated circuits.
Engineering researchers at Rensselaer Polytechnic Institute have developed a new drape made from graphene—the thinnest material known to science—which can enhance the water-resistant properties of materials with rough surfaces.
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